@GamesBrainiac That's quite handy in case you don't want ten to be ten anymore. You can change it here and have it changed throughout your whole program!! :D You should probably define variables like these for the whole set of real numbers. Never know which number you may want to change. ;D
@Tuntuni Easier to use old FORTRAN, where you could change the value of a literal by passing the literal to a function, and assigning a new value to it there.
@Tuntuni Really and truly. Though I'm sure it wasn't intended, I believe the first Fortran spec basically mandated that behavior. Some Fortran II compilers still had it too.
You start with your model, apply the model matrix (e.g. scaling your model to the appropriate size, rotating it, etc.) Then you apply the view matrix (to move the camera/objects around) Then you apply the projection matrix (for perspective/ortho)
So in the model space the coordinate system is relative to the model itself. In world, to the whole world, in view to the camera, in clip to the camera and in ndc between -1 and 1 for each direction?
@Ell It seems to be headed in that general direction, but taking an extra 10 years or so to get there. Worse, in the meantime they've done a lot that was (IMO) clearly wrong. While OpenGL had a lot of old cruft that was better off removed, they've removed a lot that's still useful along with it.
@Tuntuni You can pick the limits you want in each direction. -1 to 1 is common, but if you wanted -.001 to +1e3, you could do that.
I have this code:
#include <iostream>
#include <list>
int main()
{
typedef std::list<int> list;
int i0t[5]={-1, 2, 3, 3, 5};
list list_1(i0t, i0t+5);
list::reverse_iterator ri0 = ++list_1.rbegin();
list_1.unique();
list_1.remove(3);
int val = *ri0; // why is ...
@Tuntuni When you call (for example) glFrustum or gluLookAt, you specify the limits. I don't see anything wrong with the rest, but it's been long enough since I played with OpenGL coordinates that I can't say it's correct with any certainty either.
@JerryCoffin Ah, ok. Btw, could you answer one more thing: when specifying vertex positions in actual code, which coordinate system am I using? AFAIK the positions are always specified in the range [-1, 1] for all 3 directions, so would it be NDC?
@CaptainObvlious It's unspecified what happens to the iterator after you do something that invalidates it. Attempting to use the iterator after it's invalidated gives UB.
@Tuntuni Most code will just use model coordinates. As already noted, the range will be -1 to 1 by default, but you can change that if you want. For example, if you want to, it's entirely possible to use real-world scales, so (for example) 1.0 represents exactly one kilometer or one mile or one micron, or whatever scale you find convenient.
I'm not really sure what the applicability of infinite vals is.
hmmm
I also noticed that one property of Wide ranges that I didn't intend but keeps coming up is that if you evaluate past the end you keep getting back empty optional, instead of UB.
@DeadMG I'd have to reread the exact wording to be sure, but I don't think so. The nearest enclosing scope of your lambda is the body of f, so that's where its type is defined, so it's only visible inside of f, not in the surrounding namespace.
@DeadMG "The closure type is declared in the smallest block scope, class scope, or namespace scope that contains the corresponding lambda-expression." So yeah, I think that means the lambda is declared inside of f ("block scope").
@JerryCoffin I guess that the logical followup to that is "Does that mean that ADL can't find the operator?" since intuitively, a name declared in a nested scope of the namespace will look in there for ADL, if I remember correctly (but not quite sure)
@DeadMG True for current versions of MSVC, but (at least arguably) not for the Windows CE version. It sort of still defined a byte as 8 bits, but did not allow you to use an 8-bit type. The smallest thing you could use was a short, with sizeof == 2.
@DeadMG I think Nicol has the right conclusion, but at least partly for the wrong reason. Since the scope of the return type of f is restricted to the body of f, I don't see any way your operator + outside that scope can have any hope of finding it under any possible circumstances.
@Rapptz In so many words, template parameters and their arguments are not nice like function parameters: there's no deduction (e.g. template<typename T, T value>`) and there are some implicit conversions but they're silly.
@Borgleader In some cases, it makes sense to have all entities available as one giant list from the root (whether that's your "scene" or some other kind of container). In other cases, a tree-like scene where children can have children of children
is more desirable.
Notice that, however, in the children-of-children-of-children case, you can let the user simply decide to never nest entities if they don't want to.
Thus they get the "flat" structure they want.
It's also, really, not much work to let entities have their own children.
@ThePhD I'm trying to design the whole system at the moment, and it's not easy because of how the engine is structured, each system essentially has it's own copy of the "scene" so not only do I have to manage all the entities, I have to manage the replication and synchronisation of changes across the entire engine in a clean way.
@Rapptz Allocator have that in their interface via rebind. That's something that can be part of a concept. So instead of having Cont<V> f(Cont<T>); you can have Rebind<Cont, V> f(Cont);, and you can choose to implement Rebind<Cont<T>, V> as one of the default behaviour.
@ThePhD Yeah, since I'm going for a threaded engine (the high level design was done by intel), the explanation is that whenever a system does a change to an entity it queues up a change which the engine and these changes are propagated after each frame is completed. This avoids locking/unlocking an entity everytime a change is required.
@Ell With your idea if system A changes an entity that changes only happens until the next frame. What if inside system A, i need that change now because the entities im going to process after need to see it? With your method I cant. If i have a local duplicate im free to change it, mid frame if i need to.
@Ell Theyll see it later once the change queue has been propagated my point was if i dont have a local copy a system cant change an entity mid frame it has to wait for the changes to be propagated. If I have a local copy in each system i can change my local copy mid frame. the other systems will see the change later during propagation but at least my copy will be updated immediately
@Rapptz :) The concepts part is relevant when it's start to be not just about types, but also expressions and their semantics: for instance it's probably not enough to compute a rebound type, there should perhaps also be a way to obtain values of that type. Otherwise how can f actually do anything at all?
@Ell Last one will be correct, or i could implement an importance system. But honestly I've been going through the use cases in my head and there should be minimal to no conflict
I've done some threaded engine stuff, and there should be no reason for double buffers or basically any synchronization for persistent objects (i.e. more than function-local, say)
the whole "Run one system on one thread, run X systems concurrently" design is slow and doesn't scale past about 2-3 cores
Also, there are 2 types of decompositions in the design im following, a) functional decomposition (1 system/thread), b) data decomposition (each system will treat multiple entities at once)
I don't know if you've noticed, but the number of cores has gone up a lot since 2008... a design from then probably isn't designed to scale to a 4 or 6 core desktop or console
not to mention that it's full of things like "global managers" which should be a giant warning sign to anyone
so after my brief reading of it, my primary advice is to throw it in the bin
@DeadMG You didnt read it enough. As for the singleton managers, I've made them un-singleton. It was actually breaking another part of their design if they were to be singletons.
@JerryCoffin When you're doing a game, the vast majority of tasks even when added together can't stress a single core, and then a couple of tasks are vastly more heavyweight. So once you have more cores than the very-heavy tasks, you're wasting.
@DeadMG Almost anything that attempts to explicitly breakdown "core 0 will do X, core 1 will do Y, core 2 will do Z" is generally laughable (not to mention almost always a crappy design).
@Borgleader Because if instead, they put the thread pool to doing all physics at once, they would no longer have to expend massive amounts of time and complexity synchronizing with the Graphics task.
@DeadMG I'd also add that you seem to be restricting it (almost) exclusively to a fairly limited subset of games though. Just for example, if you're talking about a server for an MMORPG, the multiple-processes model can have quite a bit more to recommend it.
@JerryCoffin If you're talking about something like an MMORPG server, it's a bit of a different bucket because you only really have two tasks- game simulation, and then some I/O, you don't have any audio or rendering or anything like that, and the game rules tend to be very simple. But for this case, I would say that the primary thing you have to do is run the simulation on all cores simultaneously- if networking and such aren't the primary bottlenecks anyway.
I have this code:
#include <iostream>
#include <list>
int main()
{
typedef std::list<int> list;
int i0t[5]={-1, 2, 3, 3, 5};
list list_1(i0t, i0t+5);
list::reverse_iterator ri0 = ++list_1.rbegin();
list_1.unique();
list_1.remove(3);
int val = *ri0; // why is ...
